Some new research on a
bacterial predator that feeds on other bacteria may lead to new
ammunition against biofilms. The research is published in the June 2011
issue of the Journal of Bacteriology.

Bacterial pathogens
frequently form biofilms, which adhere to surfaces, and which are far
more resistant to antibiotics than are individual bacteria. Biofilms
are the culprits in a wide variety of infections, which range from
minor problems to major chronic problems, to the lethal.

The predatory bacteria, members of the genus Bdellovibrio,
eat their prey, larger, oft-pathogenic bacteria, from the inside. They
have other amazing attributes, including their incredible speed, 100
body lengths per second, propelled by a single sheathed
flagellum, which leads their student, Liz Sockett of the University of
Nottingham, UK, to characterize them as the Bugatti Veyron (top speed
250 mpg) of the microbial world. But in the new research, Sockett’s
colleagues Carey Lambert and Andy Fenton show that Bdellovibrio bacteriovorus can switch “engines”—who knew it had two?—and crawl along at a snail-like 20 body lengths per hour. That laid back locomotion “lets the Bdellovibrio
exit from a bacterial prey cell which it has finished digesting, and
crawl across a solid surface to find other bacterial prey to invade,”
says Sockett.

It is important to understand and preserve this laid back form of locomotion “if Bdellovibrio
are to be used in the future to kill pathogenic bacteria on solid
surfaces, like medical biofilms, where there may be too little liquid
for swimming,” says Sockett. Others, she says, have identified the
similarly slow engines in the Bdellovibrio relatives, the Myxobacteria, and comparing the two engines may illuminate the mechanics in ways that could lead to medical applications, she says.

As for those medical
applications, suffice it to say that biofilms play a role in urinary
tract infections, and middle ear infections; they form on catheters, on
teeth and in gums (dental plaque, and gingivitis, respectively), and
they are common in lethal infections such as cystic fibrosis and
endocarditis. “The hope is that one day Bdellovibrio in slow gear will mop them up.”